不同金属/适配体双功能复合磁性纳米材料的制备及其对外泌体的富集性能

Exosomes, which are extracellular vesicles with sizes of 30-150 nm, contain proteins, lipids, RNA, etc., which can reflect important information about parental cells. They also have unique structures and can perform characteristic biological functions. Although the release of exosomes is a normal process, tumor cells release more exosomes, and the contents can induce cancer progression. Exosomes are widely distributed in body fluids at high concentrations and are easy to obtain; hence, the collection of exosomes released by tumor cells has become one of the main directions in tumor liquid biopsy. In order to ensure the reproducibility and consistency of liquid biopsy results, it is necessary to develop methods for enriching exosomes in sufficient yield and purity from complex samples. Based on the size, hydrophobic proteins, and characteristic proteins of exosomes, various methods for exosome separation and purification have been developed, such as ultracentrifugation, polymer precipitation, and immunoaffinity methods. An aptamer (Apt) is an oligonucleotide chain with a total length of 20-100 nt, which has ligand binding properties and can be used to detect different types of drugs and biomolecules at the nanomolar level. Characteristic proteins on the surface of exosomes such as CD63, CD9, and CD81 are often used as exosomes markers. At present, a variety of aptamer sequences targeting the characteristic proteins of exosomes have been reported. Zirconium and titanium cations as well as the oxides of these metals show high affinity to the phospholipid bilayer on the exosome surface and are used in the separation and purification of exosomes. Metal organic frameworks (MOFs) can provide a wealth of metal oxide affinity sites to interact with the phospholipid bilayer membrane, and their diverse organic ligands can provide numerous modification sites to bind with aptamers. In this study, different metal/aptamer dual-functional composite magnetic nanomaterials were prepared by exploiting the surface chemistry and biological characteristics of exosomes for the enrichment and purification of exosomes. Because of the specific affinity of the aptamers toward the target membrane protein on the exosome surface and the affinity of the titanium or zirconium oxide toward the phospholipid bilayer membrane of exosomes, dual-functional magnetic nanomaterials can greatly improve the enrichment capacity and separation selectivity of exosomes. Fe(3)O(4)@Zr-MOFs was used as the substrate to fabricate the dual functional MOFs/metal oxide aptamer composite magnetic nanomaterial Fe(3)O(4)@Zr-MOFs-Apt. UiO-66-NH(2) was grown in situ on the surface of Fe(3)O(4) by a solvothermal method to form a Zr-MOFs layer, and aptamer-CD63 was covalently bonded to the amino group of the organic ligand of the MOFs. The magnetic bimetallic metal organic framework Fe(3)O(4)@Zr-Ti-MOFs, which was fabricated via a layer-by-layer assembly approach, was used as the substrate to prepare the dual functional MOFs/metal oxide aptamer composite Fe(3)O(4)@Zr-Ti-MOFs-Apt via coordination bond formation between the metal site on the Fe(3)O(4)@Zr-Ti-MOFs and the aptamers. The third dual functional MOFs/metal oxide aptamer composite magnetic nanomaterial, Fe(3)O(4)@TiO(2)-Apt, was prepared by using Fe(3)O(4)@TiO(2) as the substrate via coordination bond formation between the metal site on Fe(3)O(4)@TiO(2) and the aptamers. Considering model exosomes extracted by ultracentrifugation and urine as samples, this paper compared the enrichment performance of materials modified with the same quality of aptamers and different levels of metal oxides. The dual-functional composite magnetic nanomaterials modified with different metals/aptamers were used for the enrichment of urine exosomes. The obtained exosomes were lysed and identified by mass spectrometry, and 233, 343, and 832 exosomal proteins were identified. This result also shows that dual-functional magnetic nanomaterials can fully combine the high selectivity of the nucleic acid aptamer and the high enrichment capacity of the metal oxides. The rapid, efficient separation and purification of exosomes in biological samples has excellent application potential. The material design and purification methods also provide a new idea for the development of new exosome-enrichment materials.